CN110677949A

CN110677949A - Lamp control method and system and electronic equipment

Info

Publication number: CN110677949A
Application number: CN201911127569.3A
Authority: CN
Inventors: 邹高迪
Original assignee: Shenzhen Merrytek Technology Co Ltd
Current assignee: Shenzhen Merrytek Technology Co Ltd
Priority date: 2017-12-27
Filing date: 2017-12-29
Publication date: 2020-01-10
Also published as: US20220353973A1; EP3735108A4; WO2019127317A1; US11778704B2; CN108184286A; EP3735108A1

Abstract

The invention discloses a control method and a control system of a lamp and an electronic device, wherein the control system comprises a scheme generation unit and a control unit which is communicably connected with the scheme generation unit, wherein the scheme generation unit generates a control scheme according to an optical real image of an irradiated object, and the control unit controls the state of the lamp according to the content of the control scheme when executing the control scheme, so that the state of the lamp is matched with the state of the irradiated object, thereby being beneficial to improving the display effect of the irradiated object.

Description

Lamp control method and system and electronic equipment

Technical Field

The present invention relates to the field of lighting devices, and in particular, to a method and a system for controlling a lighting device, and an electronic device.

Background

The lamp has many applications in the display field, wherein the application of the lamp is beneficial to improving the display effect of the displayed object, for example, when a plurality of lamps are combined for use, each lamp can be used for improving the display effect of the displayed object in a mode of providing different types of light rays and irradiating the displayed object from different angles. For example, when a static object to be displayed, such as a product to be sold, is displayed, the light provided by the lamp can improve the aesthetic appearance of the object to be displayed, and this display method is widely used in clothing, accessories sales places, and food sales places. For another example, when dynamic exhibited objects (wherein the exhibited objects may be actors, models, animals, dynamic props, etc.) are exhibited at places such as a stage, a T-station, etc., the light provided by the lamp can more comprehensively and better exhibit the ideas of guides and designers.

It is well known that the chromaticity (mainly including color temperature and color) and illuminance of the light of the lamp need to be matched with the displayed object and the surrounding environment of the displayed object to improve the display effect. The light of the lamp is not matched with any one of the displayed object and the surrounding environment of the displayed object, so that the application of the lamp not only can not increase the display effect, but also can bring negative influence to the display effect.

For the clothing, the accessory selling places and the food selling places, the installation angle and the light of the lamp arranged in the places are determined by designers or lampholders according to the type of the initially displayed object, and once the installation angle and the light of the lamp are determined initially, the installation angle and the light of the lamp are difficult to change, however, the type of the displayed object changes along with the passage of time (such as the change of seasons), and once the type of the displayed object changes, the installation angle and the light of the lamp are not matched with the displayed object, so that the display effect of the displayed object is influenced. Although the type of the displayed object is changed, the lamp and the type of the displayed object can be matched by adjusting the installation angle of the lamp and the light of the lamp, for general staff in the places, the knowledge of the light distribution is relatively lacked, the general staff without the knowledge of the light distribution is difficult to match the installation angle of the lamp and the light of the lamp with the displayed object by adjusting the state of the lamp, and operators in the places are difficult to bear the cost of experienced designers or light operators.

In a place such as a stage or a T-table, it is necessary to dynamically display an object to be displayed, and since the installation angle of a lamp and the lighting thereof are different depending on the movement of the object to be displayed and the movement of the object to be displayed, an experienced lighting engineer is often required to perform an operation on the spot in the course of dynamically displaying the object to be displayed. However, a large number of lamps are often used in places such as stages and T-stands, and there are many drawbacks in adjusting these lamps in real time. Firstly, a single lamplight engineer is difficult to operate a large number of lamps simultaneously; secondly, although the dimming operation of each group of lamps can be completed by grouping a large number of lamps and then handing over the dimming operation of each group of lamps to different light operators, the matching of the lamps of different groups controlled by different light operators is easy to be defective due to the acquaintance among the light operators, and once the matching of the lamps of each group of lamps is defective, the display effect of the displayed object is influenced. In addition, the cost of the lamplight operators is often expensive, and a large number of lamplight operators are used for controlling the lamps on the spot, so that the display effect is difficult to ensure, and the cost is high.

Disclosure of Invention

The invention aims to provide a control method and a control system of a lamp and electronic equipment, wherein the control system can improve the display effect of a displayed object.

The invention aims to provide a control method and a control system of a lamp and electronic equipment, wherein the control system can improve the display effect of the displayed object at lower cost.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the control system is capable of controlling a state of at least one lamp, so as to match the state of the lamp with a state of a displayed object, thereby improving a displaying effect of the displayed object. For example, the control system can control at least one parameter of color temperature, illumination and color of the lamp to be adjusted so that the state of the lamp matches with the state of the exhibited object, thereby improving the exhibiting effect of the exhibited object.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the control system can control the lamp according to a real-time state of the displayed object, so that the state of the lamp can be adjusted in real time, and the state of the lamp is matched with the state of the displayed object, thereby improving a display effect of the displayed object.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the control system can automatically adjust the state of the lamp according to the real-time state of the displayed object, so as to match the state of the lamp with the state of the displayed object. That is, the control system can actively adjust the state of the lamp according to the state of the displayed object without human intervention in the whole process, thereby realizing the automatic control of the lamp.

An object of the present invention is to provide a control method and a control system for a lamp and an electronic device, wherein the control system provides an information collecting unit, and the information collecting unit obtains a real-time status of the displayed object in a manner of collecting an optical real image about the displayed object.

An object of the present invention is to provide a control method and a control system for a lamp and an electronic device, wherein the control system provides a processing module, wherein the processing module can distinguish an optical real image of an illuminated object from an optical real image of a display environment according to the optical real image of the displayed object, so that subsequently, the control system can better display the illuminated object by controlling a state of the lamp.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the control system provides a light mixing module, and the light mixing module can mix the chromaticity of an optical real image of a displayed object in a preset light mixing manner to obtain a light ray group.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the processing unit provides a detection unit, wherein the detection unit can perform chromaticity detection on the clew to obtain a detection result, and the type of the clew can be determined according to the detection result. For example, the detection unit may be capable of detecting an RGB combination ratio value of the clew, from which the type of the clew may be determined. Or the detection unit can detect the chromaticity tendency of the clew, and the type of the clew can be determined according to the chromaticity tendency of the clew.

An object of the present invention is to provide a control method and a control system of a lamp, wherein the processing unit provides a retrieval unit and an expert database in which data corresponding to at least one chromaticity to be output of each type of the clew is stored, wherein the retrieval unit is capable of retrieving the chromaticity to be output corresponding to the detection result in the expert database according to the detection result.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the control system provides a scheme generating unit and a control unit, the scheme generating unit can generate a control scheme according to the chromaticity to be output, and the control unit can control the state of the lamp according to the content of the control scheme when executing the control scheme, so that the lamp can project light of a suitable type to the irradiated object at a suitable angle, thereby improving the display effect of the irradiated object.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the control system provides a scheme generating unit and a control unit, the scheme generating unit can provide an adjusting scheme according to a real-time optical real image of the displayed object, and the control unit can adjust the state of the lamp according to the content of the adjusting scheme when executing the adjusting scheme, so as to further improve the display effect of the illuminated object.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the information collecting unit acquires an optical real image of the displayed object in a manner of being communicably connected to at least one image acquiring device.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the image capturing device is capable of obtaining a real-time optical real image of the displayed object in a manner of obtaining the real-time optical real image of the displayed object in real time.

An object of the present invention is to provide a control method and a control system for a light fixture and an electronic device, wherein the information collecting unit of the control system is capable of obtaining the clew about the optical real image of the exhibited object in a manner of being communicably connected to at least one color sensor.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the control system acquires an optical real image of a displayed object after emitting light rays of a predetermined type to the displayed object, and can determine chromaticity of the optical real image of the displayed object according to a characteristic value of a color of the acquired optical real image of the displayed object and a characteristic value of a color of the light rays emitted to the displayed object, and in such a manner, the control system can obtain more accurate chromaticity of the optical real image of the displayed object.

An object of the present invention is to provide a control method and a control system for a light fixture and an electronic device, wherein the control system can reduce or shield the influence of ambient light on an acquired optical real image of a displayed object in a manner of emitting light rays with a predetermined type to the displayed object, for example, the control system can reduce or shield the influence of ambient light on the acquired optical real image of the displayed object in a manner of emitting white light to the displayed object, so that the control system can obtain more accurate chromaticity of the optical real image of the displayed object in the future.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the information collecting unit can obtain a brightness signal of the displayed object for subsequent use in adjusting the operating state of the lamp, for example, adjusting the illuminance of the light output by the lamp, so that the operating state of the lamp can be more matched with the displayed object.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the brightness of the displayed object can be preset, so that the brightness can be subsequently used to adjust the working state of the lamp, for example, adjust the intensity of light output by the lamp, in such a way, the working state of the lamp can be more matched with the displayed object.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the electronic device can be conveniently connected to at least one lamp and at least one image capturing device, so as to conveniently control the state of the lamp by the electronic device to match the state of the lamp with the state of the irradiated object captured by the image capturing device.

An object of the present invention is to provide a control method and a control system for a lamp, and an electronic device, wherein the electronic device can be conveniently moved, so as to facilitate expansion of the application range of the electronic device.

According to an aspect of the present invention, a control system of a lamp is provided for controlling at least one lamp to irradiate an irradiated object with light, wherein the control system comprises:

a recipe generating unit, wherein the recipe generating unit comprises a control recipe generating module, wherein the control recipe generating module generates a control recipe according to the optical real image of the irradiated object; and

a control unit, wherein the control unit comprises a control module, wherein the control module is communicatively connected to the control scheme generation module, the luminaire is controllably connected to the control module, wherein the control module controls the state of the luminaire in accordance with the content of the control scheme when executing the control scheme.

According to an embodiment of the invention, the control system further comprises:

a processing unit, wherein the processing unit mixes the chromaticity of the optical real image of the irradiated object to obtain a light ray mass;

a detecting unit, wherein the detecting unit is communicably connected to the processing unit, wherein the detecting unit is used for detecting the chromaticity of the light ray mass to obtain a detection result;

an expert database, wherein the expert database provides at least one data of chromaticity to be output; and

a retrieval unit, wherein the retrieval unit is communicably connected to the detection unit and the expert database, and the control project generation module is communicably connected to the retrieval unit, wherein the retrieval unit retrieves one of the to-be-output chromaticities corresponding to the detection result from the expert data, the retrieved to-be-output chromaticity corresponding to the optical real image of the irradiated object.

an information collecting unit, wherein the information collecting unit obtains a clew of optical real images related to the irradiated object;

a detecting unit, wherein the detecting unit is communicably connected to the information collecting unit, wherein the detecting unit is used for detecting the chromaticity of the light ray mass to obtain a detection result;

an expert database, wherein the expert database provides at least one data of chromaticity to be output; and a retrieval unit, wherein the retrieval unit is communicably connected to the detection unit and the expert database, and the control project generation module is communicably connected to the retrieval unit, wherein the retrieval unit retrieves one of the to-be-output chromaticities corresponding to the detection result from the expert data, the retrieved to-be-output chromaticity corresponding to the optical real image of the irradiated object.

According to an embodiment of the present invention, the control system further includes an information collecting unit, wherein the information collecting unit is communicably connected to the processing unit, wherein the information collecting unit acquires an optical real image of the irradiated object by an image acquiring device in such a manner that the information collecting unit is communicably connected to the image acquiring device.

According to an embodiment of the present invention, the recipe generation unit includes an adjustment recipe generation module, the control unit includes an adjustment module communicably connected to the adjustment recipe generation module, the luminaire is controllably connected to the adjustment module, wherein the adjustment recipe generation module generates an adjustment recipe according to the real-time optical real image of the object to be illuminated, and the adjustment module adjusts the state of the luminaire according to the content of the adjustment recipe when executing the adjustment recipe.

According to an embodiment of the present invention, the processing unit further includes a processing module and a light mixing module, the light mixing module is communicably connected to the processing module and the detecting unit, wherein the processing module determines the chromaticity of the optical real image of the irradiated object by analyzing the optical real image of the irradiated object, and the light mixing module mixes the chromaticity of the optical real image of the irradiated object in a preset light mixing manner to obtain the light blob.

According to an embodiment of the present invention, the light mixing module mixes all chromaticities of the irradiated object in a preset light mixing manner to obtain the light clew; or the light mixing module mixes the specific chromaticity of the irradiated object in a preset light mixing mode to obtain the light clew.

According to an embodiment of the present invention, the light mixing method of the light mixing module is to average all chromaticities or specific chromaticities of the optical real image of the irradiation object.

According to an embodiment of the present invention, the processing module further includes an analyzing sub-module and a distinguishing sub-module, the distinguishing sub-module is communicatively connected to the analyzing sub-module, the light mixing module is communicatively connected to the distinguishing sub-module, wherein the analyzing sub-module analyzes an optical real image of a displayed object, and the distinguishing sub-module distinguishes the optical real image of the illuminated object from the optical real image of the displayed object according to an analysis result of the analyzing sub-module on the optical real image of the displayed object.

According to another aspect of the present invention, the present invention further provides a control method of a lamp, wherein the control method comprises the following steps:

(a) generating a control scheme according to an optical real image of an irradiated object through a control scheme generating module; and

(b) and controlling the state of at least one lamp according to the content of the control scheme when the control scheme is executed by a control module so as to irradiate the irradiated object by the light generated by the lamp.

According to an embodiment of the present invention, before the step (a), further comprising the steps of:

(c) mixing the optical real image of the irradiated object by a light mixing module to obtain a light ray cluster;

(d) carrying out chromaticity detection on the clew through a detection unit to obtain a detection result;

(e) retrieving, by a retrieval unit, a chromaticity to be output corresponding to the detection result from an expert database, wherein the chromaticity to be output corresponds to the optical real image of the irradiated object, so that in the step (a), the control scheme generation module can generate the control scheme based on the optical real image of the irradiated object.

obtaining a clew of optical real images of the irradiated objects through an information collecting unit;

carrying out chromaticity detection on the clew through a detection unit to obtain a detection result;

retrieving, by a retrieval unit, a chromaticity to be output corresponding to the detection result from an expert database, wherein the chromaticity to be output corresponds to the optical real image of the irradiated object, so that in the step (a), the control scheme generation module can generate the control scheme based on the optical real image of the irradiated object.

According to an embodiment of the present invention, before the step (c), further comprising the steps of:

(f) analyzing the optical real image of the irradiated object by a processing module to determine the chromaticity of the optical real image of the irradiated object, so that in the step (c), the light mixing module mixes the chromaticity of the optical real image of the irradiated object in a preset light mixing manner to obtain the ray cluster.

According to an embodiment of the present invention, the step (f) further comprises the steps of:

(f.1) analyzing the optical real image of the displayed object through an analysis submodule; and

(f.2) distinguishing the optical real image of the illuminated object in the optical real image of the displayed object by a distinguishing sub-module according to the analysis result of the analysis sub-module on the optical real image of the displayed object.

According to an embodiment of the present invention, after the step (b), further comprising the steps of:

(g) generating an adjusting scheme according to the real-time optical real image of the irradiated object through an adjusting scheme generating module; and

(h) and controlling the state of the lamp according to the content of the adjusting scheme when the adjusting scheme is executed through an adjusting module.

(i) an optical real image of the irradiated object is acquired by an image acquisition device through an information collection unit in a manner of being communicably connected to the image acquisition device.

According to another aspect of the present invention, in the step (i), further comprising the steps of:

(i.1) emitting a predetermined type of light to the irradiated object;

(i.2) obtaining an optical real image of the exhibited object after being irradiated by the light of the preset type; and

(i.3) obtaining the chromaticity of the optical real image of the exhibited object according to the obtained characteristic value of the color of the optical real image of the exhibited object and the characteristic value of the predetermined type of light rays emitted to the illuminated object.

According to another aspect of the present invention, the present invention further provides an electronic device, comprising:

a memory, wherein the memory is configured to store at least a portion of data resources of a control system;

a user interface, wherein the user interface is used to connect at least one light fixture and at least one image capture device; and

a central processor, wherein the memory and the user interface are each communicatively coupled to the central processor, wherein the central processor is configured to run the control system to perform the steps of:

(a) acquiring an optical real image of an irradiated object by an image acquisition device in a manner of being communicably connected to the image acquisition device through an information collection unit;

(b) generating a control scheme according to the optical real image of the irradiated object through a control scheme generating module; and

(c) controlling the state of at least one lamp according to the content of the control scheme when the control scheme is executed through a control module, so that the irradiated object is irradiated by the light generated by the lamp

According to one embodiment of the invention, the central processor is configured to operate the control system to further perform the steps of:

Drawings

Fig. 1 is a block diagram of a control system of a lamp according to a preferred embodiment of the invention.

Fig. 2 is a conceptual diagram of the control system according to the above preferred embodiment of the present invention.

Fig. 3 is a conceptual diagram of an electronic device according to the embodiment of the control system of the preferred embodiment of the invention.

Fig. 4 is a schematic diagram of an image capturing device of the electronic apparatus according to the embodiment of the control system of the preferred embodiment of the invention.

Fig. 5A and 5B are schematic diagrams of an embodiment of the control system according to the above preferred embodiment of the present invention.

Fig. 6A to 6D are schematic diagrams of another embodiment of the control system according to the above preferred embodiment of the present invention.

FIG. 7 is a flow chart of the control system according to the above preferred embodiment of the present invention.

Fig. 8A to 8D are optical real images of the displayed object obtained by the control system according to the above preferred embodiment of the present invention.

Fig. 9 is a flowchart illustrating a control method of a lamp according to a preferred embodiment of the invention.

Detailed Description

The technical scheme of the invention is specifically as follows according to the contents disclosed in the claims and the specification of the invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings for ease of description and simplicity of description, and do not indicate or imply that the referenced devices or components must be constructed and operated in a particular orientation and thus are not to be considered limiting.

It is understood that the terms "a" and "an" should be interpreted as meaning that a number of one element or element is one in one embodiment, while a number of other elements is one in another embodiment, and the terms "a" and "an" should not be interpreted as limiting the number.

Referring to fig. 1 and 2 of the present specification, a control system 100 of a lighting device according to a preferred embodiment of the present invention is disclosed and described in the following description, wherein the control system 100 is used for controlling at least one lighting device 200, so as to match the state of the lighting device 200 with the state of a displayed object 300 by adjusting the state of the lighting device 200, thereby improving the displaying effect of the displayed object 300. For example, the control system 100 can control at least one of the color temperature, the illuminance and the color of the light fixture 200 to match the state of the light fixture 200 with the state of the exhibited object 300, thereby improving the exhibiting effect of the exhibited object 300. It should be noted that, in a specific example of the control system 100 of the present invention, the matching between the state of the lamp 200 and the state of the exhibited object 300 according to the present invention means that the type of light generated by the lamp 200 (the type of light includes intensity of light, color temperature of light, illuminance, etc.) and the illumination angle of light are adapted to the color, shape, action, etc. of the exhibited object 300, so as to be beneficial to improve the exhibiting effect of the exhibited object 300.

Generally, the object 300 includes at least one object 301 and a display environment 302, wherein in some embodiments, the object 301 is in the display environment 302 in a static manner, and in other embodiments, the object 301 is in the display environment 302 in a dynamic manner. It should be understood by those skilled in the art that the display environment 302 is an environment for displaying the irradiated object 301, and the light generated by the lamp 200 mainly irradiates the irradiated object 301, so that the lamp 200 and the display environment 302 cooperate with each other to better display the irradiated object 301. It will be appreciated by those skilled in the art that the presentation environment 302 may affect the presentation of the displayed object 301.

Further, the control system 100 of the present invention can match the state of the lamp 200 with the state of the object to be displayed 300 by controlling the state of the lamp 200, so as to improve the display effect of the object to be illuminated 301. Preferably, the control system 100 is configured to improve the exhibition effect of the irradiation object 301 by matching the state of the lamp 200 with the state of the irradiation object 300 by controlling the state of the lamp 200 based on the type of the irradiation object 301, for example, the color, shape, and motion of the irradiation object 301. Of course, it should be understood by those skilled in the art that if the type of the display environment 302 is different, for example, the color of the display environment 302 is different, the requirement on the status of the light fixture 200 is also different, for example, the requirement on at least one parameter of the color temperature, the illumination intensity and the color of the light fixture 200 is also different, on the premise of achieving the same display effect. Therefore, in order to ensure the display effect of the object 301 to be displayed, it is necessary and necessary to obtain the states of the object 301 to be irradiated and the display environment 302 in real time to adjust the state of the luminaire 200 based on the real-time state of the object 301 to be irradiated. Of course, it should be understood by those skilled in the art how to take the real-time status of the display environment 302 into account to further improve the display effect of the irradiated object 301 when adjusting the status of the light fixture 200 based on the real-time status of the irradiated object 301 to match the status of the light fixture 200 with the real-time status of the irradiated object 301.

The control system 100 may be integrated into an electronic device 400 to facilitate subsequent deployment of the control system 100. For example, in a specific example, the light fixture 200 may be directly connected to the electronic device 400, and then the electronic device 400 is placed or disposed in the display environment 302, referring to fig. 2, wherein the electronic device 400 can adjust the state of the light fixture 200 according to the real-time states of the object to be illuminated 301 and the display environment 302, so that the state of the light fixture 200 matches the state of the object to be illuminated 300, thereby improving the display effect of the object to be illuminated 301.

It is worth mentioning that the type of the electronic device 400 is not limited in the control system 100 of the present invention, for example, the electronic device 400 may be, but is not limited to, a smart phone, a tablet computer, a notebook computer, a light console, and the like.

Referring to fig. 3, the electronic device 400 comprises at least one Central Processing Unit (CPU)401, at least one memory 402, and at least one user interface (I/O interface) 403, wherein the memory 402 and the user interface 403 are respectively communicably connected to the CPU 401, wherein at least a portion of the control system 100 may be stored in the memory 402, the luminaire 200 may be connected to the user interface 403, wherein the CPU 401 is capable of adjusting the status of the luminaire 200 when the CPU 401 reads and executes at least a portion of the control system 100 from the memory 402. It is worth mentioning that the types of the central processor 401, the memory 402 and the user interface 403 are not limited in the electronic device 400 of the present invention. For example, the central processing unit 401 may be, but is not limited to, a general purpose microprocessor, a special purpose microprocessor, an ASIC (application Specific Integrated circuit), a combination of a microprocessor, a special purpose processor, an ASIC, etc., and the central processing unit 401 may have other types as long as it can provide an operating system and processing capability to run various applications. Preferably, the central processor 401 is configured to operate the control system 100. The Memory 402 may be, but is not limited to, a RAM (Random access Memory), a ROM (read Only Memory), a flash Memory, an optical disc, a hard disc, a removable hard disc, a usb disk, etc., as long as it can store data and executable codes and allow the central processor 401 to read the stored data and executable codes from the Memory 402. Preferably, the memory 402 is configured to store at least a portion of the data resources of the control system 100. The user interface 403 may be, but is not limited to, a USB interface, a bluetooth interface, a Wi-Fi interface, etc.

In addition, the electronic device 400 may further include a display 404, wherein the display 404 is communicatively connected to the central processor 401, wherein the display 404 may display images and data. It is noted that the display 404 may be any suitable display, such as a Liquid Crystal Display (LCD), a Light Emitting Diode (LED) based display, an Organic Light Emitting Diode (OLED) based display, a Cathode Ray Tube (CRT) display, an analog television, a digital television, and the like. In some other specific examples of the electronic device 400 of the present invention, the display screen 404 may also be a touch screen to allow a user to interact with the electronic device 400 through the display screen 404, and the user may interact with the control system 100 through the display screen 404.

In addition, the electronic device 400 further comprises an image capturing device 405, wherein the image capturing device 405 is communicatively connected to the central processor 401 to allow the central processor 401 to capture the optical real image of the exhibited object 300 captured by the image capturing device 405. In one specific example of the electronic device 400 of the present invention, the image acquisition apparatus 405 may be directly communicably connected to the central processor 401, while in another specific example of the electronic device 400 of the present invention, the image acquisition apparatus 405 may be connected to the central processor 401 in such a manner as to be connected to the user interface 403. It should be noted that the optical real image related to the control system 100 of the present invention refers to a real image related to the displayed object 300, which may include a visible optical real image or an invisible optical real image, and the control system 100 of the present invention is not limited in this respect.

However, it will be understood by those skilled in the art that in some other specific examples of the control system 100 of the present invention, additional or additional image capture devices 405 may be connected to the central processor 401 in such a way as to be connected to the user interface 403. It should be noted that the type of the image capturing device 405 is not limited in the control system 100 of the present invention, as long as it can capture the optical real image of the exhibited object 300, and for example, the image capturing device 405 may be, but is not limited to, a camera.

Fig. 4 shows a specific example of the image capturing device 405, wherein the image capturing device 405 is used for capturing an optical real image of the displayed object 300. Specifically, the image capturing device 405 includes a photoelectric conversion chip 4051 and a lens 4052, wherein the lens 4052 is held in a photosensitive path of the photoelectric conversion chip 4051, and when the light reflected by the exhibited object 300 enters the inside of the image capturing device 405 from the lens 4052, the photoelectric conversion chip 4051 can receive the light to perform photoelectric conversion to obtain an optical real image of the exhibited object 300.

It should be noted that the number of lenses 40520 of the lens 4052 is not limited in the control system 100 of the present invention, for example, the number of lenses 40520 of the lens 4052 may be one, although those skilled in the art will understand that the number of lenses 40520 of the lens 4052 may also be two, three, four, five, six, seven or more in other possible examples of the control system 100. When the number of the mirror plates 40520 of the lens 4052 is one, the mirror plates 40520 are preferably convex lenses.

It is understood that, in some embodiments of the present invention, when the number of the lenses 40520 is one, the lenses 40520 may be further configured as an imaging aperture to generate an optical real image of the displayed object 300 by the principle of aperture imaging, or as an optical sphere. Thus, it is further understood that when the number of the mirror plates 40520 is two or more, the mirror plates 40520 may be configured to be formed by at least one combination of a convex lens, a concave lens, an optical sphere, and an imaging aperture.

Preferably, the lens 4052 can be driven to move along the photosensitive path of the photoelectric conversion chip 4051 relative to the photoelectric conversion chip 4051, so as to adjust the focal length of the image capturing device 405, thereby obtaining a better image by the image capturing device 405. Alternatively, the image capturing device 405 may be rotated so that the lens 4052 of the image capturing device 405 may be oriented in different directions, for example, when the object 301 moves in the exhibition environment 302, the image capturing device 405 may rotate synchronously with the movement of the object 301 in the exhibition environment 302, so that the image capturing device 405 may obtain the optical real image of the object 301 in real time.

Referring to fig. 1, the control system 100 includes an information collecting unit 10, a processing unit 20, a detecting unit 30, an expert database 40, a retrieving unit 50, a scenario generating unit 60, and a control unit 70, wherein the processing unit 20 is communicably connected to the information collecting unit 10, the detecting unit 30 is communicably connected to the processing unit 20, the retrieving unit 50 is communicably connected to the detecting unit 30 and the expert database 40, the scenario generating unit 60 is communicably connected to the retrieving unit 50, and the control unit 70 is communicably connected to the scenario generating unit 60.

The information collecting unit 10 obtains an optical real image of the object 300 to be displayed so as to be communicably connected to the image acquiring device 405. The information collection unit 10 and the image acquisition device 405 may be connected wirelessly or by wire. Preferably, the information collection unit 10 is communicably connected to the image acquisition device 405 in a wireless connection. The image capturing device 405 can capture an optical real image of the object 300 in real time, so as to capture the object 300. Preferably, the information collecting unit 10 can be communicably connected to the photoelectric conversion chip 4051 of the image capturing apparatus 405, so that the information collecting unit 10 can receive the optical real image of the exhibited object 300 from the photoelectric conversion chip 4051 of the image capturing apparatus 405.

Further, before the optical real image of the exhibited object 300 is acquired by the image acquiring device 405, a predetermined type of light may be firstly emitted to the exhibited object 300, for example, the color, color temperature, intensity, etc. of the light emitted to the exhibited object 300 may be preset as required, and after the light is emitted to the exhibited object 300 to illuminate the exhibited object 300, the optical real image of the exhibited object 300 is captured by the image acquiring device 405. It should be understood by those skilled in the art that, at this time, the color of the optical real image of the exhibited object 300 acquired by the image acquiring device 405 is different from the real color of the exhibited object 300, and subsequently, the chromaticity of the optical real image of the exhibited object 300 needs to be determined according to the characteristic value of the color of the acquired optical real image of the exhibited object 300 and the characteristic value of the color of the light emitted to the exhibited object 300, in such a way, the control system 100 can control the state of the lamp 200 so that the state of the lamp 200 can better match the real-time state of the exhibited object 300.

The processing unit 20 can receive the optical real image of the exhibited object 300 from the information collecting unit 10, and the processing unit 20 can analyze, process and mix the optical real image of the illuminated object 301 of the exhibited object 300 to obtain a light ray mass. Specifically, the processing unit 20 further includes a processing module 21 and a light mixing module 22, wherein the light mixing module 22 is communicably connected to the processing module 21, the processing module 21 is communicably connected to the information collecting unit 10, and the detecting unit 30 is communicably connected to the light mixing module 22.

The processing module 21 can receive the optical real image of the exhibited object 300 from the information collecting unit 10, and the processing module 21 can analyze and process the optical real image of the exhibited object 300 to obtain the optical real image of the irradiated object 301 of the exhibited object 300. The light mixing module 22 can mix the chromaticity of the optical real image of the object 301 to obtain the light ray mass about the object 301. It should be noted that the light mixing method of the light mixing module 22 for the chromaticity of the optical real image of the irradiation object 301 is not limited in the control system 100 of the present invention. For example, in an example of the control system 100 according to the present invention, the light mixing manner of the light mixing module 22 may be to obtain the light ray mass by averaging all chromaticities or specific chromaticities included in the chromaticities of the optical real image of the irradiation target 301. For example, a specific chromaticity included in the chromaticity of the optical real image of the object 301 may be a main chromaticity of the object 301, and specifically, a specific chromaticity included in the chromaticity of the optical real image of the object 301 may be a chromaticity that affects a visual effect of the object 301. In a more specific example of the control system 100 of the present invention, the light mixing module 22 may first analyze the optical real image of the object 301 to obtain RGB combination ratio values of all chromaticities or RGB values of specific chromaticities included in the optical real image of the object 301, and then average the RGB combination ratio values of all chromaticities or the RGB combination ratio values of specific chromaticities to obtain the ray clique. It will be understood by those skilled in the art that the RGB in the RGB combination proportion value according to the present invention is a color pattern, i.e., an RGB color pattern, and by providing or determining the RGB combination proportion value, a specific color of the chromaticity can be determined. It should be further understood by those skilled in the art that, in other specific examples of the control system 100 of the present invention, the light mixing module 22 may also adopt other light mixing manners, for example, the light mixing module 22 may first analyze the optical real image of the object 301 to obtain RGB combination proportion values of all chromaticities included in the optical real image of the object 301, and then mix the RGB combination proportion values of all chromaticities or RGB combination proportion values of specific chromaticities in a preset manner to obtain the ray clique, where the preset manner may be halving, doubling, decreasing by a specific amount, increasing by a specific amount, mapping to other chromaticities, and the like on the basis of the RGB values of all chromaticities or the RGB combination proportion values of specific chromaticities.

It should be noted that the above-mentioned detection method for detecting the RGB combination ratio of the chromaticity of the light ray mass related to the irradiated object 301 is only an example, and in another example of the control system 100, the chromaticity of the light ray mass related to the irradiated object 301 may be directly detected to determine the type of the light ray mass according to the chromaticity of the light ray mass.

It should be noted that, in another specific embodiment of the control system 100 of the present invention, the information collecting unit 10 may directly obtain the bolus of the irradiated object 301 of the exhibited object 300, that is, in this specific example of the control system 100, the control system 100 does not need to capture an optical real image of the irradiated object 301 of the exhibited object 300 through the image capturing device 405, and subsequently obtain the bolus of the irradiated object 301 of the exhibited object 300 by analyzing the optical real image of the irradiated object 301 of the exhibited object 300 through the processing unit 20. Specifically, in this particular example of the control system 100 of the present invention, the information collecting unit 10 is communicatively connected to at least one color sensor, wherein the color sensor may be, but is not limited to, a TCS230 type sensor, wherein the information collecting unit 10 is capable of obtaining the bolus of light about the object 301 of the object 300 to be exhibited directly through the color sensor. The detecting unit 30 may be communicably connected to the information collecting unit 10 so that the detecting unit 30 can directly perform chromaticity detection on the clew of the irradiated object 301 of the exhibited object 300 obtained by the information collecting unit 10. In general, the image obtaining unit 405 obtains the optical real image of the illuminated object 301 of the displayed object 300 and the optical real image of the display environment 302 at the same time, and then the subsequent adjustment of the state of the luminaire 200 depends more on the state of the illuminated object 301, especially, the adjustment of the state of the luminaire 200 depends almost completely on the state of the displayed object 301 when the display environment 302 is kept unchanged. Therefore, after the optical real image of the object 300 is acquired by the image acquiring unit 405, the processing module 21 is required to partition the optical real image of the object 301 and the optical real image of the display environment 302 included in the optical real image of the object 300.

Further, the processing module 21 comprises an analyzing sub-module 211 and a discriminating sub-module 212, wherein the discriminating sub-module 212 is communicatively connected to the analyzing sub-module 211, wherein the analyzing sub-module 211 is communicatively connected to the information collecting unit 10, and the light mixing module 22 is communicatively connected to the discriminating sub-module 212. The analysis sub-module 211 is capable of analyzing the optical real image of the exhibited object 300 to obtain an analysis result after receiving the optical real image of the exhibited object 300 from the information collection unit 10, the discrimination sub-module 212 is capable of discriminating the optical real image of the exhibited object 300 according to the analysis result obtained by the analysis sub-module 211 to distinguish the optical real image of the irradiated object 301 included in the optical real image of the exhibited object 300 from the optical real image of the exhibition environment 302, and the light mixing module 22 is capable of mixing the chromaticity of the optical real image of the irradiated object 301 to obtain the light ray mass.

For the exhibited object 300 in which both the exhibited object 301 and the exhibiting environment 302 are kept unchanged, after the information collecting unit 10 collects the optical real image of the exhibited object 300 acquired by the image acquiring device 300, the analyzing sub-module 211 can analyze the chromaticity variation in the optical real image of the exhibited object 300, and the distinguishing sub-module 212 can distinguish the illuminated object 301 and the exhibiting environment 302 according to the chromaticity variation in the optical real image of the exhibited object 300 analyzed by the analyzing sub-module 211, so as to distinguish the optical real image of the illuminated object 301 and the optical real image of the exhibiting environment 302. For example, referring to fig. 5A and 5B, for a food selling location, the irradiated object 301 may be meat to be sold, the display environment 302 may be a table top for placing the meat to be sold or a suspension for suspending the meat to be sold, it is understood that the meat to be sold as the irradiated object 301 and the table top and the suspension as the display environment 302 are all kept unchanged, and the image acquiring device 405 can simultaneously acquire an optical real image of the meat of the irradiated object 301 and an optical real image of the table top and the suspension as the display environment 302. In general, in order to highlight the meat serving as the irradiated object 301, the chromaticity of the table and the suspension serving as the display environment 302 is very different from the chromaticity of the meat serving as the irradiated object 301, so that subsequently, after the analysis submodule 211 analyzes the chromaticity of the meat serving as the irradiated object 301 and the chromaticity of the table and the suspension serving as the display environment 302, the discrimination submodule 212 can distinguish the optical real image of the irradiated object 301 from the optical real image of the display environment 302 according to the analysis result of the analysis submodule 211.

For the exhibited object 300 in which the illuminated object 301 changes and the exhibiting environment 302 remains unchanged, after the optical real image of the exhibited object 300 is obtained, the processing module 21 may also distinguish the optical real image of the illuminated object 301 from the optical real image of the exhibiting environment 302 by the difference between the chromaticity of the illuminated object 301 and the chromaticity of the exhibiting environment 302. In addition, in another specific example of the control system 100 of the present invention, the analysis sub-module 211 can analyze at least two optical real images of the exhibited object 300 to find a changed portion in the optical real image of the exhibited object 300, so that subsequently, the discrimination sub-module 212 can distinguish the optical real image of the illuminated object 301 from the optical real image of the display environment 302. It is understood that, after analyzing at least two optical real images of the object 300 to be displayed, a changed portion of the optical real image of the object 300 to be displayed is the optical real image of the illuminated object 301, and a unchanged portion of the optical real image of the object 300 to be displayed is the optical real image of the display environment 302. For example, referring to fig. 6A to 6D, for a model displayed on a T-table, the object 301 may be a model, the display environment 302 may be a T-table, and it is understood that the T-table as the display environment 302 remains unchanged, and the model as the object 301 moves on the T-table. After obtaining at least two optical real images of the exhibited object 300 at different times, the analysis sub-module 211 can easily determine which portions of the optical real image of the exhibited object 300 are changed and which portions are not changed by analyzing the optical real images, so that the discrimination sub-module 212 can distinguish the optical real image of the illuminated object 301 from the optical real image of the exhibiting environment 302 in the exhibited object 300.

For the exhibited object 300 in which both the illuminated object 301 and the exhibiting environment 302 are changed, after the optical real image of the exhibited object 300 is obtained, the processing module 21 may distinguish the optical real image of the illuminated object 301 and the optical real image of the exhibiting environment 302 in the optical real image of the exhibited object 300 by combining chromaticity and motion. For example, for stage exhibition, after obtaining the optical real image of the stage, the processing module 21 may distinguish the optical real image of the illuminated object 301 from the optical real image of the exhibition environment 302 in the optical real image of the exhibited object 300 by combining chromaticity and motion.

The detecting unit 30 is communicably connected to the light mixing module 22 of the processing unit 20, wherein the detecting unit 30 performs chromaticity detection on the light clusters obtained by the light mixing module 22 to obtain a detection result. For example, the detection unit 30 may perform RGB combination ratio value detection on the clew to determine an RGB combination ratio value of the clew. It is worth mentioning that different types of the clews correspond to different RGB combination ratio values. In addition, it should be understood that the RGB combination ratio value of the light ray mass corresponds to the chromaticity of the optical real image of the object 301 to be irradiated.

It should be noted that the above-listed detection unit 30 may obtain the detection result by detecting the RGB combination ratio of the clew, which is only an example and should not be construed as limiting the content and scope of the control system 100 of the present invention. That is, in other possible examples of the control system 100, the detection unit 30 may also detect other properties of the clew.

The expert database 40 provides at least one chromaticity to be outputted in a manner of being communicably connected to the memory 402 of the electronic device 400, wherein the type of chromaticity to be outputted provided by the expert database 40 is provided empirically by an experienced expert (e.g., designer, light engineer, etc.), that is, conclusions obtained by the experienced expert through a plurality of tests are stored in the memory 402 to form the chromaticity to be outputted, wherein the test contents of the experienced expert are that the object to be illuminated 301 needs to be provided with different types of light and illumination angles of light in different states in the presentation environment 302. For example, when the objects 301 to be illuminated in different states are in the same display environment 302, the types of light and the illumination angles of the light that the objects 301 to be illuminated need to provide are different, and at this time, an expert may empirically provide different chromaticities to be output and store the chromaticities to be output in the memory 402. For another example, the type of light and the irradiation angle of the pipeline that the irradiated object 301 in the same state needs to be provided in different display environments 302 are different, and at this time, the expert may provide different chromaticity to be output according to experience and store the chromaticity to be output in the memory 402.

The retrieval unit 50 is communicably connected to the detection unit 30 and the expert database 40, wherein the retrieval unit 50 is capable of receiving the detection result from the detection unit 30 and retrieving the corresponding chromaticity to be output from the expert database 40 according to the detection result. It should be understood by those skilled in the art that the chromaticity to be outputted provided by the expert database 40 corresponds to the detection result obtained by the detection unit 30 in a one-to-one manner, so that the retrieval unit 50 can retrieve the corresponding chromaticity to be outputted from the expert database 40 according to the detection result provided by the detection unit 30.

The scenario generating unit 60 includes a control scenario generating module 61, wherein the control scenario generating module 61 is communicably connected to the retrieving unit 50, wherein the control scenario generating module 61 is capable of generating a control scenario from the chromaticity to be output retrieved by the retrieving unit 50 corresponding to the detection result regarding the clew. It is worth mentioning that, the content of the control scheme is how to control the lamp 200, so as to improve the display effect of the irradiated object 301 after the light generated by the lamp 200 irradiates the irradiated object 301. For example, the light generated by the lamp 200 is strong or weak, the chromaticity of the light, the color temperature of the light, the angle of the light irradiation, and the like.

The control unit 70 comprises a control module 71, wherein the control module 71 is communicatively connected to the control scheme generation module 61, the control module 71 is communicatively connected to the luminaire 200, and the luminaire 200 is controllable by the control module 71. The control module 71 is capable of receiving the control scheme from the control scheme generating module 71, and controlling at least one of the lamps 200 according to the content of the control scheme when executing the control scheme, so as to provide light and make the light irradiate the irradiated object 301, thereby improving the display effect of the irradiated object 301.

It is worth mentioning that the type of the luminaire 200 is not limited in the control system 100 of the present invention, for example, the luminaire 200 may be, but not limited to, a dual color temperature LED light source, a WRGB light source, an RGB light source, or a combination thereof.

Further, when the control module 71 controls the lamp 200 to illuminate the illuminated object 301 according to the content of the control scheme, the image acquiring device 405 may further acquire the optical real image of the displayed object 300, and then the processing module 21 of the processing unit 20 may distinguish the optical real image of the illuminated object 301 from the optical real image of the display environment 302 by analyzing and processing the optical real image of the displayed object 300. Preferably, the image acquiring device 405 may acquire the real-time optical real image of the exhibited object 300 in a manner of acquiring the real-time optical real image of the exhibited object 300, so that subsequently, the processing module 21 of the processing unit 20 may acquire the real-time optical real image of the illuminated object 301. The recipe generation unit 60 further includes an adjustment recipe generation module 62, wherein the adjustment recipe generation module 62 is communicably connected to the processing module 21 of the processing unit 20, and the adjustment recipe generation module 62 is capable of generating an adjustment recipe from the real-time optical real image of the object 301 to be irradiated. It should be noted that, the content of the adjusting scheme is how to adjust the lamp 200, so as to further improve the display effect of the irradiated object 301 after the light generated by the lamp 200 irradiates the irradiated object 301. For example, the light generated by the lamp 200 is strong or weak, the chromaticity of the light, the color temperature of the light, the angle of the light irradiation, and the like.

The control unit 70 further comprises an adjustment module 72, wherein the adjustment module 72 is communicatively connected to the adjustment scheme generation module 62, the adjustment module 72 is communicatively connected to the luminaire 200, and the luminaire 200 is controllable by the adjustment module 72. The control module 72 is capable of receiving the adjustment scheme from the adjustment scheme generating module 62, and controlling at least one of the lighting fixtures 200 according to the content of the adjustment scheme when executing the adjustment scheme, so as to adjust the type of the light irradiated to the irradiated object 301, thereby further improving the display effect of the irradiated object 301.

Fig. 7 shows a specific process 700 of the control system 100 of the present invention, wherein the control system 100 is used to control the state of at least one of the lamps 200, so that the state of the lamp 200 matches the state of the object 300 to improve the display effect of the object 301. The process 700 includes several stages as follows.

In stage 701, the image capturing device 405 captures an optical real image of the displayed object 300. For example, at the stage shown in fig. 6A and 6B, one or more image capturing devices 405 may be disposed on top of the T-stage, and the image capturing devices 405 may obtain an optical real image of the displayed object 300 by taking a picture or a video. It is understood that the optical real image of the object to be displayed 300 includes not only the optical real image of the T-stage as the display environment 302 but also the optical real image of the model as the object to be illuminated 301. Preferably, the image capturing device 405 is rotatable, so that the image capturing device 405 can rotate along with the movement of the model as the object 301 to be illuminated, so that the optical real image of the object 301 is kept at a specific position of the optical real image of the object 300 to be displayed at all times, for example, in such a way that the optical real image of the object 301 to be illuminated can be kept at a middle position of the optical real image of the object 300 to be displayed at all times. Fig. 8A and 8B respectively show the optical real images of the exhibited object 300 acquired by the image acquiring device 405 at different time periods, wherein the model has different motions, wherein the optical real image of the exhibited object 300 shown in fig. 8A corresponds to the state of the exhibited object 300 shown in fig. 6A, and correspondingly, the optical real image of the exhibited object 300 shown in fig. 8B corresponds to the state of the exhibited object 300 shown in fig. 6B.

Stage 702, the information collecting unit 10 acquires an optical real image of the exhibited object 300 from the image acquiring device 405. The information collecting unit 10 is communicably connected to the image acquiring device 405 so that the information collecting unit 10 can receive the optical real image of the object 300 to be displayed from the image acquiring device 405 after the optical real image of the object 300 to be displayed is acquired by the image acquiring device 405.

Stage 703, the analyzing sub-module 211 analyzes the optical real image of the exhibited object 300, and the distinguishing sub-module 212 distinguishes the optical real image of the illuminated object 301 in the optical real image of the exhibited object 300 according to the analysis result of the analyzing sub-module 211 on the optical real image of the exhibited object 300. For example, in a specific example of the control system 100 of the present invention, the analysis sub-module 212 can analyze the optical real image of the exhibited object 300 shown in fig. 8A and 8B, and after analyzing the optical real image of the exhibited object 300 shown in fig. 8A and 8B, it can obtain which portions of the optical real image of the exhibited object 300 are changed and which portions are static in fig. 8A and 8B, and the distinguishing sub-module 212 can distinguish the changed portions of the optical real image of the exhibited object 300 as the optical real image of the illuminated object 301 and distinguish the static portions of the optical real image of the exhibited object 300 as the optical real image of the exhibiting environment 302, referring to fig. 8C. It is understood that once the optical real image of the illuminated object 301 and the optical real image of the presentation environment 302 in the optical real image of the object 300 to be presented are determined, for example, once the optical real image of the model and the optical real image of the T-stage are determined, the model and the T-stage can also be determined, and thus the position of the model in the T-stage. However, it should be understood by those skilled in the art that in other possible examples of the control system 100 of the present invention, the analyzing sub-module 211 may also make the distinguishing sub-module 212 subsequently distinguish the optical real image of the illuminated object 301 from the optical real image of the exhibit 302 in the exhibited object 300 by analyzing the chromaticity of the exhibited object 300, or the analyzing sub-module 211 may make the distinguishing sub-module 212 subsequently distinguish the optical real image of the illuminated object 301 from the optical real image of the exhibit 302 in the exhibited object 300 by analyzing the chromaticity and the action of the exhibited object 300.

Stage 704, the light mixing module 22 mixes the chromaticity of the optical real image of the object 301 to obtain the light ray mass. Preferably, the light mixing module 22 mixes all chromaticities or specific chromaticities of the optical real image of the illuminated object 301 in a preset light mixing manner to obtain the light ray mass, for example, the light mixing module 22 may mix all chromaticities or specific chromaticities of the optical real image of the clothing and the skin color worn by the model. The light mixing method of the light mixing module 22 is to average all chromaticities or specific chromaticities of the optical real image of the irradiation object 301. However, it should be understood by those skilled in the art that the manner of averaging all chromaticities or specific chromaticities of the optical real image of the illuminated object 301 by the light mixing module 22 is only an example, and does not limit the content and scope of the control system 100 of the present invention.

Stage 705, the detecting unit 30 performs chromaticity detection on the clew to obtain the detection result. For example, the detection unit 30 may detect the RGB values of the clew to determine the RGB values of the clew.

Stage 706, the retrieving unit 50 retrieves the chromaticity to be output corresponding to the detection result from the expert database 40 according to the detection result, wherein the chromaticity to be output corresponds to the optical real image of the illuminated object 301.

Stage 707, the control scheme generating module 61 generates the control scheme according to the chromaticity to be output. The content of the control scheme is how to control the lamp 200 so as to improve the display effect of the irradiated object 301 after the light generated by the lamp 200 irradiates the irradiated object 301.

In stage 708, the control module 71 controls the state of the luminaire 200 according to the content of the control scheme when executing the control scheme, so that the state of the luminaire 200 matches the state of the irradiated object 301, thereby improving the exhibition effect of the irradiated object 301. Referring to fig. 6C, the state of the lamp 200 is adjusted relative to the state of the lamp 200 shown in fig. 6A and 6B, so that the light generated by the lamp 200 is irradiated onto the model, thereby improving the display effect of the model.

Stage 709, the image acquiring device 405 acquires a real-time image of the exhibited object 300. Referring to fig. 8D, the image capturing device 405 can further capture the optical real image of the exhibited object 300 shown in fig. 6C, wherein the optical real image of the exhibited object 300 shown in fig. 8D corresponds to the state of the exhibited object 300 shown in fig. 6C. Preferably, the image capturing device 405 is capable of capturing the real-time optical real image of the object 300 in real time to obtain the real-time optical real image of the object 300. It is understood that the image capturing device 405 can obtain a real-time optical real image of the irradiated object 301.

Stage 710, the adjustment scheme generating module 62 generates the adjustment scheme according to the real-time optical real image of the illuminated object 301. The content of the adjustment scheme is how to adjust the lamp 200, so as to further improve the display effect of the irradiated object 301 after the light generated by the lamp 200 irradiates the irradiated object 301.

In stage 711, the adjusting module 72 adjusts the state of the luminaire 200 according to the content of the adjusting scheme when executing the adjusting scheme, so that the state of the luminaire 200 better matches the state of the irradiated object 301, and the display effect of the irradiated object 301 is further improved. Referring to fig. 6D, the state of the lamp 200 is adjusted relative to the state of the lamp 200 shown in fig. 6C, so that the light generated by the lamp 200 is irradiated onto the model, thereby improving the display effect of the model.

Fig. 9 shows a control method 900 of the luminaire 200, wherein the control method 900 comprises the following steps:

step 901, mixing the optical real image of the irradiated object 301 by a light mixing module 22 to obtain a light ray group;

step 902, performing chromaticity detection on the clew through a detection unit 30 to obtain a detection result;

step 903, retrieving an output chromaticity corresponding to the detection result from an expert database 40 through a retrieval unit 50, wherein the output chromaticity corresponds to the optical real image of the irradiated object 301;

step 904, generating a control scheme according to the optical real image of the irradiated object 301 through a control scheme generating module 61;

step 905, controlling the state of at least one lamp 200 according to the content of the control scheme when the control scheme is executed by a control module 71, so as to irradiate the irradiated object 301 by the light generated by the lamp 200;

step 906, generating an adjustment scheme according to a real-time optical real image of an object 300 to be displayed through an adjustment scheme generating module 62; and

step 907, adjusting the state of the lamp 200 according to the content of the adjustment scheme by an adjusting module 72 when executing the adjustment scheme, so as to irradiate the irradiation object 301 with the light generated by the lamp 200.

It will be appreciated by persons skilled in the art that the above embodiments are only examples, wherein features of different embodiments may be combined with each other to obtain embodiments which are easily conceivable in accordance with the disclosure of the invention, but which are not explicitly indicated in the drawings.

It will be appreciated by persons skilled in the art that the embodiments of the invention described above and shown in the drawings are given by way of example only and are not limiting of the invention. The objects of the invention have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the examples, and any variations or modifications of the embodiments of the present invention may be made without departing from the principles.

Claims

1. A control method of a lamp is characterized by comprising the following steps:

(A) detecting the chromaticity of a light ray mass of an optical real image of an irradiated object to obtain a detection result;

(B) providing a chroma data to be output corresponding to the detection result; and

(C) and generating a control method according to the chromaticity data to be output so as to control the state of the lamp based on the control method, thereby irradiating the irradiated object by the light generated by the lamp.

2. The control method according to claim 1, wherein in the step (a), chromaticity of the optical real image of the irradiated object is mixed to obtain the bolus with respect to the optical real image of the irradiated object.

3. The control method according to claim 2, wherein in the method, the entire chromaticity of the irradiation object is mixed in a preset mixing manner to obtain the light ray mass.

4. The control method according to claim 2, wherein in the method, the specific chromaticity of the irradiated object is mixed in a preset mixing manner to obtain the clew.

5. The control method according to claim 2, wherein in the method, the entire chromaticity or a specific chromaticity of the optical real image of the irradiation object is averaged to obtain the clew.

6. The control method according to claim 3, 4 or 5, wherein before the step (A), the control method further comprises the step of:

emitting a predetermined type of light to the irradiated object;

obtaining an optical real image of the irradiated object after being irradiated by a predetermined type of light; and

and obtaining the chromaticity of the optical real image of the irradiated object according to the obtained characteristic value of the color of the optical real image of the irradiated object and the characteristic value of the light ray of the preset type emitted to the irradiated object.

7. A control system of a lamp for controlling light of at least one lamp to irradiate an irradiated object, comprising:

a detection unit, wherein the detection unit detects the chromaticity of a light ray mass of the optical real image of the irradiated object to obtain a detection result;

a retrieval unit, wherein the retrieval unit is communicably connected to the detection unit, wherein the retrieval unit retrieves a chromaticity data to be output corresponding to the detection result;

a control scheme generation module, wherein the control scheme generation module is communicatively connected to the retrieval unit, wherein the control scheme generation module generates a control scheme according to the chrominance data to be output; and

a control module, wherein the control module is communicably connected to the control scheme generation module, wherein the control module controls the state of the lamp according to the content of the control scheme when executing the control scheme, so as to irradiate the irradiated object with the light generated by the lamp.

8. The control system according to claim 7, further comprising a processing unit, wherein the detection unit is communicably connected to the processing unit, wherein the processing unit mixes the chromaticity of the optical real image of the irradiated object to obtain the clew.

9. The control system according to claim 8, wherein the processing unit further comprises a processing module and a light mixing module, the light mixing module is communicatively connected to the processing module and the detecting unit, wherein the processing module determines the chromaticity of the optical real image of the irradiated object by analyzing the optical real image of the irradiated object, wherein the light mixing module mixes the chromaticity of the optical real image of the irradiated object in a preset light mixing manner to obtain the light blob.

10. The control system according to claim 9, wherein the light mixing module mixes all chromaticities of the illuminated object in a preset light mixing manner to obtain the light clew.

11. The control system according to claim 9, wherein the light mixing module mixes the specific chromaticity of the irradiated object in a preset light mixing manner to obtain the light clew.

12. The control system according to claim 9, wherein the light mixing manner of the light mixing module is to average all chromaticities or a specific chromaticity of the optical real image of the irradiated object.

13. The control system according to claim 7, 8, 9, 10, 11, or 12, further comprising an adjustment plan generation module and an adjustment module communicably connected to the adjustment plan generation module, wherein the adjustment plan generation module generates an adjustment plan based on the optical real image of the illuminated object, and the adjustment module adjusts the state of the luminaire based on the content of the adjustment plan when executing the adjustment plan.

14. A control method of a lamp is characterized by comprising the following steps:

(a) distinguishing an optical real image of an illuminated object from an optical real image of a display environment in an optical real image of a displayed object;

(b) generating a control scheme according to the optical real image of the irradiated object; and

(c) and when the control scheme is executed, controlling the state of at least one lamp according to the content of the control scheme so as to irradiate the irradiated object by the light generated by the lamp.

15. The control method according to claim 14, wherein in the step (a), the optical real image of the illuminated object and the optical real image of the display environment in the optical real image of the displayed object are distinguished according to a chromaticity change of the optical real image of the displayed object.

16. The control method according to claim 14, wherein in the step (a), the optical real image of the illuminated object and the optical real image of the display environment in the optical real image of the displayed object are distinguished according to a combination of a chromaticity change and a motion change of the optical real image of the displayed object.

17. The control method according to claim 14, 15 or 16, wherein the step (b) further comprises the steps of:

mixing the optical real image of the irradiated object to obtain a ray cluster;

detecting the clew of the optical real image of the irradiated object to obtain a detection result;

and retrieving to-be-output chroma data corresponding to the detection result so as to generate the control scheme according to the to-be-output chroma data.

18. The control method according to claim 17, wherein in the method, the optical real image of the irradiated object is acquired by at least one image acquisition device.

19. The control method according to claim 18, wherein before acquiring the optical realization of the irradiated object by the image acquisition device, the control method further comprises the steps of:

emitting a predetermined type of light to the irradiated object;

and obtaining the optical real image of the irradiated object according to the obtained characteristic value of the color of the optical real image of the irradiated object and the characteristic value of the light ray of the preset type emitted to the irradiated object.

20. The control method according to claim 17, wherein in the method, the entire chromaticity of the irradiation object is mixed in a preset mixing manner to obtain the light ray mass.

21. The control method according to claim 17, wherein in the method, the specific chromaticity of the irradiated object is mixed in a preset mixing manner to obtain the clew.

22. The control method according to claim 17, wherein in the method, the entire chromaticity or a specific chromaticity of the optical real image of the irradiation object is averaged to obtain the clew.

23. A control system of a lamp for controlling light of at least one lamp to irradiate an irradiated object, comprising:

a processing module, wherein the processing module comprises an analysis sub-module and a discrimination sub-module communicatively connected to the analysis sub-module, wherein the discrimination sub-module discriminates the optical real image of the illuminated object from the optical real image of the displayed object according to an analysis result of the analysis sub-module on the optical real image of the displayed object;

a control plan generation module, wherein the control plan generation module is communicatively connected to the processing module, wherein the control plan generation module generates a control plan based on the optical real image of the object to be illuminated; and

a control module, wherein the control module is communicably connected to the control scheme generation module, wherein the control module controls a state of at least one lamp according to contents of the control scheme when executing the control scheme, so as to irradiate the irradiated object with light generated by the lamp.

24. The control system according to claim 23, wherein the discrimination sub-module discriminates the optical real image of the illuminated object from the optical real image of the display environment in the optical real image of the displayed object according to a chromaticity variation of the optical real image of the displayed object.

25. The control system of claim 23, wherein the discrimination sub-module distinguishes the optical real image of the illuminated object from the optical real image of the presentation environment in the optical real image of the displayed object according to a combination of chromatic variation and motion variation of the optical real image of the displayed object.

26. The control system of claim 23, 24 or 25, further comprising:

a light mixing module, wherein the light mixing module is communicably connected to the processing module, wherein the light mixing module mixes the chromaticity of the optical real image of the irradiated object to obtain the light clew;

a detecting unit, wherein the detecting unit is communicably connected to the light mixing module, and wherein the detecting unit performs chromaticity detection on the clew to obtain a detection result; and

a retrieval unit, wherein the retrieval unit is communicably connected to the detection unit and the control scheme generation module, wherein the retrieval unit retrieves a chromaticity data to be output corresponding to the detection result to allow the control scheme generation module to generate the control scheme based on the chromaticity data to be output.

27. The control system of claim 26, further comprising a recipe generation module and a recipe module communicatively coupled to the recipe generation module, wherein the recipe generation module generates a recipe based on the real-time optical real image of the object to be illuminated, and the recipe module adjusts the state of the light fixture based on the contents of the recipe when the recipe is executed.